Method and systems for administering virtual machines to client devices

ABSTRACT

Methods for executing application programs in computer systems including a host computer formed of a plurality of servers configured to execute at least one virtual machine each hosting a primary user session associated to a remote client and at least one additional server may involve transmitting a primary session stream between the virtual machine and the remote client to emulate the presence, at the remote client, of a physical computer system. The execution of the application program may be initiated in a secondary user session hosted on the additional server and preparing a secondary session stream of the secondary user session. The primary and the secondary session streams may be aggregated to form an aggregated session stream, and the aggregated session stream may be processed at the remote client to emulate the execution of the application program on the physical computer system.

CROSS-REFERENCE TO RELATED APPLICATIONS

This is a continuation of U.S. patent application Ser. No. 16/213,327,filed Dec. 7, 2018, which, pursuant to 35 U.S.C. § 119(a), claims thebenefit of the filing date of French Patent Application Serial No.1858532, filed Sep. 20, 2018, for “A Method for Executing an ApplicationProgram in a Computer System,” the contents of each of which are herebyincorporated herein in their entirety by this reference.

TECHNICAL FIELD

This disclosure describes methods and systems for executing anapplication program in a computer system. More particularly, thisdisclosure describes methods and systems for more efficientlyadministering virtual machines to client devices utilizingunconventional hardware configurations and software programming fordivision of resources.

BACKGROUND

US2017/0228851 and FR3047576 disclose computing system configurationswherein the user interface devices (display, keyboard, etc.) areseparated from the application processing component. The user interfacedevices are located at the desktop of the user (also referred to as the“client”) while the processing and storage components of the computerare placed in a remote hosting location. The user interface devices thenhave access, at the host computer, to a dedicated virtual machinethrough a network (most usually the Internet), the virtual machineemulating the required processing, storage, and other computingresources. The host computer hosts the operating system and softwareapplications utilized by the clients, thus limiting processing resourceson the clients' side.

The host computer usually consists of a plurality of physical computingsystems (servers) each hosting a plurality of virtual machines. Eachvirtual machine is connected to a client and provides a dedicatedvirtual environment to emulate the functions of a physical personalcomputer, including graphic data processing, and provides the displayinformation of the user session to the client screen. The data to bedisplayed are transferred through the network to the client. The clientpossesses sufficient computing resources to receive the data flow anddisplay them. The client is also provided with input/output devices(keyboard, mouse, etc.) to exchange control information or instructionto the virtual machine, via the network.

The user interface devices are therefore heavily dependent on the hostcomputer that fulfills the computational roles for the clients.

BRIEF SUMMARY

To this effect, the disclosure relates to methods for executing anapplication program in computer systems, the computer systemscomprising, for example: a host computer formed of a plurality ofservers configured to execute at least one virtual machine each hostinga primary user session associated to a remote client; and at least oneadditional server.

Methods in accordance with this disclosure may involve transmitting aprimary session stream between the virtual machine and the remote clientto emulate the presence, at the remote client, of a physical computersystem; initiating the execution of the application program in asecondary user session hosted on the additional server and preparing asecondary session stream of the secondary user session; and aggregatingthe primary and the secondary session stream to form an aggregatedsession stream, and processing the aggregated session stream at theremote client to emulate the execution of the application program on thephysical computer system.

By combining virtual machines running on a shared server and additionalservers for execution of certain computing intensive applicationprograms, the proposed method provides to the user an excellent level ofservice, while reducing (e.g., minimizing) the computing resources,notably hardware resources, necessary to achieve this level of service.

According to further non-limitative features of the disclosure, eithertaken alone or in any technically feasible combination:

-   -   initiating the execution of the application program comprises        intercepting a user request for executing an application program        or for installing an application program, by a monitoring        process of the primary user session;    -   the secondary user session is hosted directly on the additional        server or the secondary user session is hosted in a virtual        machine executing on the additional server;    -   the computing system comprises a plurality of servers and the        step of initiating the execution of the application program        comprises the selection of the additional server among the        plurality of servers;    -   the selection of the additional server comprises selecting among        the plurality of additional server, the additional server that        is best configured to execute the application program;    -   initiating the execution of the application program comprises        initiation of the secondary user session on the additional        server;    -   the computing system comprises a storage server associated to        the server of host computer and an additional storage server        associated with the additional server;    -   initiating the execution of the application program comprises        copying at least part of a user context stored in the storage        server to the additional storage server;    -   the primary and secondary session streams are communicated to        the remote client and the step of aggregating the primary and        the secondary session streams is performed at the remote client;    -   wherein the computing system comprises an aggregation server,        the primary and secondary session streams are communicated to        the aggregation server, and wherein the step of aggregating the        primary and secondary session streams is performed at the        aggregation server.

BRIEF DESCRIPTION OF THE DRAWINGS

Many other features and advantages of this disclosure will becomeapparent from reading the following detailed description, whenconsidered in conjunction with the accompanying drawings, in which:

FIG. 1 represents a computing system configuration according to oneembodiment of the present disclosure;

FIG. 2 represents the main step of a method according to the disclosure.

DETAILED DESCRIPTION

In the following description, detailed descriptions of known functionsand elements that may unnecessarily make the gist of this disclosureobscure will be omitted.

Methods in accordance with this disclosure provide that, in such acomputer system configuration, additional processing capacity beprovided to the client. More particularly, the proposed method enablesdedicating, for a period of time, computing resources for executing acomputing intensive application program, and without allocating thoseresources permanently to a client.

In FIG. 1 , a computing architecture comprises a host computer 1presenting a plurality of servers 2. Host computer 1 also comprises astorage server 6 for providing storage capacity. The servers 2 may beconfigured to host one or a plurality of virtual machines 3, along withits operating system and applications. Virtualization allows a pluralityof virtual machines 3 to be hosted into each server 2 while providing aplurality of completely isolated virtual environments within a singleserver 2.

Each of the virtual machine 3 in host computer 1 may be dedicated to oneparticular user. The user contexts, i.e., the operating system,application programs and user data that are dedicated to each user, arestored in respective portions of the nontransitory storage capacitymanaged by storage server 6. The users interact with their dedicatedvirtual machine 3, from remote clients 4, 4′ each connected to the hostcomputer 1 through a network, such as the Internet. Since most, if notall, of the processing is performed at host computer 1, the remoteclients 4, 4′ may be kept very simple and may comprise, for instance, asimple terminal, network connector and basic input/output devices(keyboard, mouse, etc.), such as represented by remote client 4 on FIG.1 . Alternatively, suitable remote clients 4, 4′ could be a standardpersonal computer, with its own CPU, graphic card, peripherals, etc.,such as represented by remote client 4′. Remote clients 4, 4′ are notlimited to a particular form, and may consist of any computing device,such as a tablet, a personal computer or a smartphone.

Each server 2 is preferably hosting fewer than ten virtual machines 3 toprovide sufficient computing resources to each virtual machine 3 forexecuting applications with a sufficient level of service. Each virtualmachine 3 is created upon client connection and is associated to thecorresponding user context. To this end, a management process running ona master server 5 of host computer 1 may be provided to initiate,terminate and, more generally, operate the virtual machines of hostcomputer 1. Each virtual machine 3 includes a virtual CPU, a virtualmain memory, one virtual or physical graphic card, and other resources.Each virtual machine 3 constitutes or is equivalent to a user session,and a large number of such user sessions may be executed on the servers2 of the host computer 1.

To emulate the presence of a physical computer system at the remoteclient terminal, the host computer 1 provides, through the network, tothe remote client 4, 4′ display, sounds and control information forinput/output devices located at the remote site. Conversely, the remoteclients 4, 4′ are providing to the host computer 1 control informationfrom input/output devices located at the remote site (keyboard, mouse),and possibly other forms of data such as display and sound informationprovided by a USB or built in camera and microphone of the remote client4, 4′, or network devices at the remote client locations, such asprinters.

A capture process of each user session 3 prepares the display data,sound data and other types of information for their communication to theassociated client 4, 4′. The capture process also collects theinformation received from the client 4, 4′ so that they can be processedby the user session 3. Similarly, the remote clients 4, 4′ are providedwith appropriate hardware and/or software resources to decode/encode theinformation received from host computer 1 before they are displayed, ormore generally used on the client side, or the information transmittedto the host computer 1. All the information exchanged between a usersession 3 and a remote client 4, 4′ will be referred to as “sessionstream” in the present disclosure.

Pursuing description of FIG. 1 , the computing architecture alsocomprises a plurality of additional servers 2′ and at least oneadditional storage server 6′, here located in a secondary host computer1′. The additional servers 2′ form computing resources that can beallocated to one remote client 4, 4′, non-permanently, for executing acomputing intensive application program. Additional storage server 6′ isstoring at least one such application program, and preferably aplurality of such application programs. Advantageously, the applicationprograms stored on additional storage server 6′ are known to requireimportant computing resources, such that their execution in a virtualenvironment may appear imperfect to a user. The application programsstored in the secondary host computer 1′ may be executed directly on theadditional servers 2′, as it will be explained in greater details in afurther portion of this disclosure. Each additional server 2′ ispreferably constituted of high-end computing components (processor(s),memory, one or more graphic cards, storage) such that applications mayexecute effectively on such a server. In a particular embodiment, theadditional servers 2′ are configured to execute efficiently theapplication programs stored in additional storage server 2′. Someadditional servers 2′ may be set up, in terms of graphic card type,memory capacity, type of CPU, to perfectly match the need of aparticular program of the additional storage server 2′. This embodimentis advantageous since it allows to adjust the computing resources ofsecondary host computer 1′ to what is exactly needed to executeefficiently the selected application programs stored in additionalstorage server 6′. Since these application programs are executed on theadditional servers 2′, it is not necessary for the servers 2 of the hostcomputer 1 to be formed of higher end components, in term of performanceand capacity.

It is not necessary that the additional servers 2′ and storage server 6′be located in a separate secondary host computer 1′ as represented inFIG. 1 . When this is the case, the host computer 1 and secondary hostcomputer 1′ are communicating over a communication link 8 such thatinformation may flow without excessive delay from one host to the other.More generally, there may be any number of interconnected hostcomputers, each host comprising a plurality of servers 2 for hostingvirtual machines and/or additional servers 2′. In one configuration, theservers 2, additional servers 2′, storage and additional storage server6, 6′ are all part of a single host computer 1. Storage and additionalstorage may be part of a single storage server of host computer 1.

A method according to the present disclosure proposes to execute anapplication program stored in additional storage server 6′ on anadditional server 2′. This execution may be performed directly on theadditional server 2′ or within a virtual machine hosted on theadditional server 2′. By “directly,” it is meant that a user session isexecuted on the physical hardware of the additional server 2′, withoutthe use of a virtual environment. In other terms, the computingresources of the additional server are directly allocated to theexecution of the user session and of the application program.

According to this method, a user is initially logged from remote client4, 4′ into a primary user session, hosted in a server 2 of host computer1. A primary session stream is transmitted between the user session andthe remote client, to emulate the presence of a physical computer systemat the remote client, as explained in detail in the preceding part ofthis disclosure. This step is represented as step S1 on FIG. 2 .

The user initiates the execution of an application program that requiresimportant computing resources, by any appropriate means, e.g., using amouse or a command line or by voice control. Rather than starting theexecution of the application program within the virtual machine, theapplication program is executed in a secondary user session on anadditional server 2′, as this is represented as step S2 on FIG. 2 .

Detecting the initiation of the application program may be performed inmultiple manners. For instance, each primary user session may execute abackground monitoring process, launched at the startup of the primaryuser session, and configured to intercept a user's request forinitiating an application program. This process may compare therequested application program with a list of applications whoseexecution should be performed on the additional server 2′. This list maycorrespond to the list of application programs stored in secondarystorage server 6′.

Alternatively, the monitoring process may intercept a user's request forinstalling a new application program, and instead, if the newapplication program is identified as requiring high-processing power,installing a redirect program in the user session. The redirect programmay appear to the user, on the desktop of the primary user session,identical to the requested new program but is configured to initiate theexecution of the application program on additional server 2′ rather thanin the virtual environment of server 2 of host computer 1.

In another variant, the monitoring process may provide the choice to theuser, upon intercepting a request to execute an application program orto install a new application program, to initiate the execution of thisprogram in the primary user session of server 2 or to a secondary usersession on an allocated additional server 2′.

Different substeps may be required to initiate the execution of theapplication program on additional server 2′. Those substeps may becoordinated, for instance, by a coordination process running on themaster server 5 of host computer 1 or of secondary host computer 1′. Amessage from the monitoring process or redirect program indicating therequesting user session and/or remote client and the requestedapplication program may be addressed to the coordination process totrigger the execution of at least some of these substeps.

The substeps may comprise the selection of one additional server 2′ fromthe secondary host computer 1′ for execution of the requestedapplication program, from the available additional servers 2′. Theallocated additional server will be used, possibly exclusively, forexecuting the requested program. In some instances, it will host aunique secondary user session. In other instance, it will host one or avery limited number of virtual machines for executing one or a limitednumber of user sessions. Advantageously, this substep selects the serverthat is most adapted, in terms of hardware and/or softwareconfiguration, to the execution of the requested software program. Forthat purpose, the coordination process may maintain a list ofapplication programs/additional servers that are best matched together.

The substep also comprises the initiation of a secondary user session inthe allocated additional server 2′, either directly or within a virtualmachine, and uploading the requested application program from additionalstorage server 6′ in the user session.

The substeps may also comprise the transfer of at least part of the usercontext from storage server 6 of host computer 1 to the additionalstorage server 6′ of secondary host computer 1′. In this way, therequested application program may be executed on the additional server2′ while having access to the user data such that the secondary usersession and the application program may be set up according to userpreexisting preferences and access user preexisting documents or data.

The substeps comprise, within the secondary user session, the executionof a capturing process, similar to the one being executed in the primaryuser session, to prepare a secondary session stream. Accordingly, thesecondary session stream incorporates all display data, sound data, andother information such as control data to be exchanged between thesecondary user session and the remote client 4, 4′. In a particularembodiment, not all the data and information are incorporated in thesecondary session streams, but only those display data that relates tothe application program. For instance, only display data of the sessionwindow into which the application program is running are incorporated inthe secondary session stream. Position and/or size of the window mayalso be incorporated into the secondary session stream, so that streameddata may be reconstituted on the receiving side.

Referring back to the general method for executing an applicationprogram of FIG. 2 , the method further comprises a step S3 ofaggregating the primary and secondary session streams to form anaggregated stream. This aggregated session stream is then processed atthe remote client 4, 4′, for instance, to display a unified session onthe remote client screen. To the user, the application program appearsto be executed on the remote client, on the emulated physical computersystem.

The aggregation of session streams may be performed at the remote client4, 4′. In such case, primary and secondary session streams are eachtransmitted to that client separately over the network. The client 4, 4′is provided with appropriate hardware and software for preparing theaggregated stream before they are displayed or processed to the user.Alternatively, primary and secondary session streams are directed by therespective capture process of the primary and secondary user session toa separate aggregation server. The aggregation server, that may belocated at host computer 1 or secondary host computer 1′ or at any otherlocation, combines the two streams before communicating the aggregatedstream to the remote client 4, 4′ over the network. The step ofdirecting primary and secondary session streams may be performed, forinstance, by the coordination process of the master server 5.

By aggregating streams, it is meant that only relevant portions of thetwo streams are integrated into the resulting integrated stream. Moreprecisely, the secondary session stream is given priority and onlycomplementary information from the primary session stream, if necessary,is incorporated into the aggregated stream. For instance, if theapplication program is running in a full-screen mode in the secondaryuser session, the aggregation server or remote client will discard alldisplay data from the primary session stream, such that only displaydata from the secondary user session will be displayed at the remoteclient 4, 4′. It may, however, incorporate sound data and otherinformation from the primary session stream into the aggregated stream.If the application program is running in a window mode of the secondaryuser session, the aggregation server or remote client will complementthe display data of the secondary session, outside of the window, withdisplay data from the primary session stream.

By providing an additional server 2′ for the execution of a requestedapplication program, within a secondary user session that has preferablyaccess to the user context, the application program can be executed veryefficiently, for instance, without excessive execution latency. Byaggregating the primary and secondary user session, the dedicatedresources are provided transparently to the user, as if he was operatinga single very high end personal computer at its remote location.

Once the application program is terminated by the user, the secondaryuser session may be closed and the additional server 2′ released. Userdata that have been duplicated into the additional storage server 6′ maybe updated into the user context of storage server 6 of host computer 1,to reflect the changes that may have been made while the applicationprogram was running. Primary session stream is redirected to the remoteclient if it was directed to an aggregation server.

The disclosed method and computing architecture combining virtualmachines running on a shared server and additional servers for executionof certain computing intensive application programs allow to provide tothe user an excellent level of service, while minimizing the computingresources, notably hardware resources, necessary to achieve this levelof service. It notably avoids transferring the complete primary sessionfrom one server to another, more powerful, server when the user wishesto execute computing intensive application programs. Such transfer wouldintroduce unacceptable delays for the users.

Other variations to the disclosed embodiments can be understood andeffected by those skilled in the art in practicing the claimedinvention, from a study of the drawings, this disclosure, and theappended claims.

What is claimed is:
 1. A method for executing an application program ina computer system, the computer system comprising: a host computerformed of a plurality of servers configured to execute at least onevirtual machine each hosting a primary user session associated to aremote client; and at least one additional server; the methodcomprising: transmitting a primary session stream of the primary usersession between the virtual machine and the remote client to emulate apresence, at the remote client, of a physical computer system;intercepting, by a monitoring process of the primary user session, arequest for executing or installing the application program in theprimary session; initiating the execution of the application program ina secondary user session hosted on the at least one additional serverand preparing a secondary session stream of the secondary user session;aggregating the primary session stream and the secondary session streamto form an aggregated session stream by prioritizing display of thesecondary session stream over non-complementary information from theprimary session stream, and transmitting the aggregated session streamfor processing at the remote client to emulate the execution of theapplication program on the physical computer system.
 2. The method ofclaim 1, wherein the secondary user session is hosted directly on the atleast one additional server.
 3. The method of claim 2, wherein thesecondary user session is hosted in a virtual machine executed on the atleast one additional server.
 4. The method of claim 1, whereininitiating the execution of the application program comprises selectingthe at least one additional server from among the plurality of servers.5. The method of claim 4, wherein selecting the additional servercomprises selecting the additional server having a hardwareconfiguration that is best configured to execute the application programfrom among the plurality of servers.
 6. The method of claim 1, whereinthe computing system comprises a storage server operatively connected tothe plurality of servers of the host computer and an additional storageserver operatively connected to the at least one additional server. 7.The method of claim 6, wherein initiating the execution of theapplication program comprises copying at least part of a user contextstored in the storage server to the additional storage server.
 8. Themethod of claim 1, wherein aggregating the primary session stream andthe secondary session stream comprises discarding all information fromthe primary session stream when the secondary session stream indicatesthat the application program is running in full-screen mode.
 9. Themethod of claim 1, wherein the computing system comprises an aggregationserver, the primary and secondary session streams are communicated tothe aggregation server, and wherein aggregating the primary andsecondary session streams is performed at the aggregation server.
 10. Asystem for administering virtual machines to client devices, comprising:a primary host computer comprising a first plurality of servers; and asecondary host computer comprising a second plurality of servers;wherein the primary host computer comprises a first storage serverhaving a first nontransitory memory device storing software instructionsthat, when executed, cause the primary host computer to: initiate aprimary session stream comprising at least an operating system for avirtual machine utilizing the first plurality of servers in response toa request from a client device; wherein the secondary host computercomprises a secondary storage server having a second nontransitorymemory device storing software instructions that, when executed, causethe secondary host computer to: initiate a secondary session streamcomprising an application program for the virtual machine utilizing thesecond plurality of servers in response to a request from a clientdevice passed to the secondary host computer by the primary hostcomputer; and wherein the software instructions stored by the firstnontransitory memory device, when executed, cause the primary hostcomputer to aggregate the primary session stream and the secondarysession stream to form an aggregated session stream by prioritizingdisplay of the secondary session stream over non-complementaryinformation from the primary session stream; and wherein the softwareinstructions stored by the first nontransitory memory device, whenexecuted, cause the secondary host computer to terminate the secondarysession stream in response to a request from the client device passed tothe secondary host computer by the primary host computer.
 11. The systemof claim 10, wherein the first plurality of servers has a first hardwareconfiguration and the second plurality of servers has a second,different hardware configuration.
 12. The system of claim 11, whereinthe second hardware configuration of the second plurality of servers isbetter adapted to execution of the application program than the firsthardware configuration of the first plurality of servers.
 13. The systemof claim 10, wherein the software instructions stored by the firstnontransitory memory device, when executed, cause the primary hostcomputer to aggregate the primary session stream and the secondarysession stream by discarding all information from the primary sessionstream when the secondary session stream indicates that the applicationprogram is running in full-screen mode.
 14. The system of claim 10,wherein the software instructions stored by the first nontransitorymemory device, when executed, cause the primary host computer toaggregate the primary session stream and the secondary session stream byincorporating only complementary information from the primary sessionstream with all information from the secondary session stream,aggregation resulting in the complementary information from the primarysession stream being located outside a window of the secondary sessionstream.
 15. The system of claim 10, wherein the software instructionsstored by the second nontransitory memory device, when executed, causethe secondary host computer to directly allocate resources from thesecond plurality of servers to the secondary session stream.
 16. Thesystem of claim 10, wherein the software instructions stored by thefirst nontransitory memory device, when executed, cause the primary hostcomputer to compare a request to open the application program to a listof available programs on the primary host computer and the secondaryhost computer and to initiate the secondary session stream only with theapplication program is not available on the primary host computer and isavailable on the secondary host computer.
 17. A system for administeringvirtual machines to client devices, comprising: a primary host computercomprising a first plurality of servers; and a secondary host computercomprising a second plurality of servers; wherein the primary hostcomputer comprises a first storage server having a first nontransitorymemory device storing software instructions that, when executed, causethe primary host computer to: initiate a primary session streamcomprising at least an operating system for a virtual machine utilizingthe first plurality of servers in response to a request from a clientdevice; wherein the secondary host computer comprises a secondarystorage server having a second nontransitory memory device storingsoftware instructions that, when executed, cause the secondary hostcomputer to: initiate a secondary session stream comprising anapplication program for the virtual machine utilizing the secondplurality of servers in response to a request from a client devicepassed to the secondary host computer by the primary host computer; andwherein the software instructions stored by the first nontransitorymemory device, when executed, cause the primary host computer toaggregate the primary session stream and the secondary session stream toform an aggregated session stream by prioritizing display of thesecondary session stream over non-complementary information from theprimary session stream; and wherein the software instructions stored bythe first nontransitory memory device, when executed, cause the primaryhost computer to transmit preexisting user data to the secondary hostcomputer to set up the application program at the secondary hostcomputer in accordance with the preexisting user data.